KR20220135796A - Hybrid handrail light - Google Patents

Abstract

The present invention relates to a hybrid handrail light, and more specifically, to a hybrid handrail light, which illuminates a lighting installed on a handrail using sunlight and wind power. The hybrid handrail light includes: a handrail light fixture; a handrail lighting installed on the handrail lighting fixture; a photovoltaic generator which collects sunlight to generate power; a wind generator which generates electricity using rotational force caused by wind; and a handrail.

Description

Hybrid handrail lighting {HYBRID HANDRAIL LIGHT}

The present invention relates to a hybrid railing lighting, and more particularly, to a hybrid railing lighting capable of illuminating a lighting installed on a railing using sunlight and wind power.

In general, railings, fences, etc. are installed to protect a certain area or to indicate the boundary of the area, and are formed to have a certain shape while having a certain height and to have a beautiful appearance, and are installed to decorate the aesthetics.

In addition, the railing for the bridge is installed to have a predetermined height in the vertical direction at both ends of the bridge, and is installed to prevent a running vehicle, etc. from being separated from the bridge.

Such handrails, fences, etc. have a problem in that the handrails or fences are not easily visible at night, so that they can easily come into contact with people or vehicles who enjoy walking or cause a collision to break the railing or injure the human body.

In addition, there is a problem in that the handrail or fence does not know that a person approaches the boundary area, and for this, a separate facility that requires maintenance cost has to be installed, so there is a problem in that the cost increases.

In particular, there was a problem that the wind power and solar power generation could not be used at the same time because the solar power was too little and the wind power was not strong in the place where the railing or the fence was installed.

Republic of Korea Patent Publication No. 10-0499091 (2005. 06. 23.) Republic of Korea Patent Publication No. 10-1811142 (2017. 12. 14.)

The present invention has been devised to solve the above problems, and when installing a railing or fence, the reflected light of the sun provided at various locations can be accumulated, and it can respond quickly to changes in the strength of the wind using a wind shaft. It is to provide a hybrid railing lighting that can obtain energy by using magnetic power to generate power and installing wind power and solar power together.

Another object of the present invention is to produce electricity and illuminate using wind power generation and solar power generation using wind power generation and solar power generation for railings or fences that are difficult to use wind power and solar power, and hybrid railing for excellently improving solar light collecting efficiency. to provide lighting.

An object of the present invention is to provide a hybrid railing lighting lamp capable of generating wind power by rotating a blade even in a low wind or no wind state and illuminating the railing lighting 365 days a year.

The present invention minimizes the frictional force by levitating the wind shaft, on which the blade for wind power generation is installed, in the air using magnetic force, thereby greatly increasing the rotational force even when the wind power is small, so that the efficiency of the wind power generation can be excellently improved, and the lighting is operated all the time It is an object of the present invention to provide a hybrid railing lighting that can be

The purpose of the present invention and its technical problems are not limited to the technical problems described above. Accordingly, other technical problems not mentioned will be clearly understood by those of ordinary skill in the art to which the present invention belongs from the following description.

The present invention relates to a railing lighting lamp in which lighting is installed on a railing or fence, including a hollow cylindrical support 10, and a railing lighting lamp having a lower inner pillar 18 installed on the inner side of the post 10 ( 102) and; a photovoltaic generator 106 having a heat collecting plate 16 installed on the upper surface of the railing light 104 to collect and generate solar light; A wind power generator 108 having a wind shaft 24 that is levitated in the air by magnetic force to minimize frictional force and is generated while the blade 109 rotates, and a rising protrusion ( 20) is formed, and a plurality of ascending magnetics 22 are installed on the upper surface of the ascending protrusion 20, and a descending concave portion 26 is formed at the lower end of the wind shaft 24, and the descending concave portion 26 of the A plurality of descending magnets 28 opposite to the ascending magnetic 22 are installed on the lower surface, and a mutual repulsive force is generated between the ascending magnetic 22 and the descending magnetic 28 to generate the wind shaft 24. The blade 109 by levitating in the air to minimize frictional force and: a wind generator cover 118 installed on the outer side of the wind generator to protect the blade 109 of the wind generator 108 and to introduce only one-way wind. characterized in that

A lower magnetic bearing 30 into which a magnetic 31 is interpolated is installed on the lower outer circumferential surface of the wind shaft 24, and the upper portion close to the lower magnetic bearing 30 prevents and supports the flow of the wind shaft 24 A lower ceramic bearing 32 for An upper magnetic bearing 36 in which a magnetic 37 is interpolated is installed in the upper portion close to the upper ceramic bearing 34, and the magnetic 31 and the magnetic 37 are opposed to each other to generate a repulsive force. It is preferable to be installed on the wind shaft 24 .

The blade shaft 43 of the blade 109 of the wind generator 108 further includes a non-powered rotating unit 114 to generate electricity by rotating the blade 109 by magnetic force when there is no wind, the non-powered rotating unit ( 114), a flange portion 38 is formed on the upper portion of the wind shaft 24, a rotating groove 40 is formed in the central portion of the flange portion 38, and a plurality of is provided with a rotating magnet 42 of the blade shaft 43, and a rotating protrusion 46 coupled to the rotating recess 40 is formed at the lower portion of the blade shaft 43, and a plurality of fixing magnets 48 are formed on the rotating protrusion 46. is provided, and the rotating magnetic 42 and the fixed magnetic 48 are installed to generate a mutual repulsive force, so that the fixed magnetic 48 is pushed in one direction by the repulsive force of the rotating magnetic 42 and at the same time the blade shaft 43 ) is preferably installed to rotate.

A plurality of levitation magnets (60) installed on the upper surface of the holding (10) and; A plurality of levitation magnets (61) that are installed to face and face the plurality of levitation magnets (60) to generate a mutual repulsive force and are inserted and installed in the flange portion (44) of the blade shaft (43). It is preferable to provide a blade shaft lifting means 116 that is installed to float the blade shaft 43 provided with the blade 109 by a predetermined distance in the air.

As described above, the present invention can be installed on a railing or fence installed in a boundary area, and has the effect of being installed in a narrow place and a place with little wind or solar power, and a railing or fence using both wind power generation and solar power generation It has the effect of greatly reducing safety accidents by allowing the lighting of the lamp to be operated at all times.

1 is a perspective view showing the structure of a hybrid railing lighting lamp of the present invention;
2 is an exploded cross-sectional view showing the structure of a hybrid railing lighting lamp of the present invention;
3 is a cross-sectional view showing the structure of the hybrid railing lighting lamp of the present invention;
4 is a cross-sectional view showing a non-powered rotating part of the hybrid railing lighting of the present invention;
5 is a view showing the structure of another embodiment of the hybrid railing lighting of the present invention;
6 is an operation state diagram of FIG. 5
7 is a perspective view showing the cover structure of the wind power generator of the hybrid railing lighting of the present invention;

In describing the specific embodiments below, various specific contents have been prepared to more specifically explain and help the understanding of the invention.

However, those of ordinary skill in the art having enough knowledge in this field to understand the present invention will recognize that it can be used without these various specific details.

In some cases, it should be mentioned in advance that parts that are commonly known and not largely related to the invention in describing the invention are not described in order to avoid confusion in describing the invention, which is the right to interact between the components of the invention. will be within range.

Hereinafter, a specific embodiment according to the hybrid railing lighting of the present invention will be described.

1 is a perspective view showing the structure of the hybrid railing lighting of the present invention, FIG. 2 is an exploded cross-sectional view showing the structure of the hybrid railing lighting of the present invention, and FIG. 3 is a cross-sectional view showing the structure of the hybrid railing lighting of the present invention, FIG. 4 is a cross-sectional view showing the non-powered rotating part of the hybrid handrail lighting of the present invention.

And, Figure 5 is a view showing the structure of another embodiment of the hybrid railing lighting of the present invention, Figure 6 is an operation state diagram of Figure 5, Figure 7 is a perspective view showing the cover structure of the wind power generator of the hybrid railing lighting of the present invention to be.

The hybrid railing lighting 100 of the present invention will be described with reference to FIGS. 1 to 7 , as shown in FIG. 1 , the hybrid railing lighting 100 includes a railing lighting lamp post 102 and the railing lighting lamp post. It includes a railing lighting lamp 104 installed in 102, a solar generator 106 that collects sunlight to generate electricity, and a wind generator 108 and a railing 200 that generate electricity using rotational force from wind power.

The hybrid railing lighting lamp 100 is vertically erected so that a plurality of railing lighting posts 102 are installed so that a plurality of posts 10 are spaced apart at regular intervals, and extending to the left of the upper end of the railing lighting fixture 102 . A railing lighting lamp 104 is installed, and a solar generator 106 is installed on the upper surface of the railing lighting lamp 104 installed on the railing lighting lamp post 102, and extending upward from the upper end of the railing lighting lamp post 102. A wind power generator 108 is fixedly installed on the handrail 200 .

A handrail 200 is installed in the horizontal direction to prevent safety accidents such as collision, fall, and stepping between the plurality of railing lighting posts 102 and the railing lighting lamp posts 102 .

And, the generator 110 is built-in to enable generation of electricity by the wind shaft 24 rotated by the wind power generator 108 in the inner part of the railing lighting post 102, the railing lighting fixture 102 ), a plurality of charging modules 112 are installed inside the lower end.

The plurality of charging modules 112 are of a detachable type so that the electricity generated by the generator 110 can be charged and buffered, and then detached and used, and it is preferable to use a prismatic lithium ion secondary battery.

The configuration of the generator 110, the configuration of the charging module 112, and the electrical circuit and technical configuration for generating and generating electricity are conventional techniques and thus will not be specifically mentioned.

A non-powered rotating unit 114 is installed at the lower inner side of the wind power generator 108, and the non-powered rotating unit 114 generates rotational force in a low-rotation state by rotating it using magnetic force in a windless state without wind. It is for rotating the blade 109 to generate power.

Figure 2 is an exploded cross-sectional view of the present invention, the lighting horizontal bar 12 is extended in the left direction of the upper end of the railing lighting lamp post 102 provided with the vertically installed post 10, the lighting horizontal bar ( At the end of 12), a lighting 14 is installed.

At this time, a photovoltaic generator 106 is installed on the upper surface of the lighting 14 .

The photovoltaic generator 106 is made of a plurality of cells and is provided with a heat collecting plate 16 installed to generate electricity after absorbing and collecting sunlight.

The heat collecting plate 16 of the photovoltaic generator 106 generates electricity and stores the electricity generated in the charging module 112 to be described later. Since the electricity generation and power generation technology and the power storage technology are conventional technologies, they will not be described in detail in the present invention.

The post 10 is made in the shape of a hollow cylindrical column, and the lower inner column 18 is inserted into the inner part of the post 10 .

The lower inner pillar 18 is formed in a cylindrical shape, and a plurality of lifting magnets 22 are installed on the upper portion of the lower inner pillar 18 .

The upward magnetic 22 is preferably installed so that a magnetic force is formed upward, and is installed so as to lift the lower end of the wind shaft 24 to be described later by magnetic force to levitate it in the air.

A wind shaft 24 is coupled to the upper portion of the lower inner pillar 18 and is inserted and installed in the inner portion of the post 10 .

A lower magnetic bearing 30 and a lower ceramic bearing 32 are coupled and installed on the outer side of the wind shaft 24 , and the upper ceramic bearing 34 and the upper ceramic bearing 32 are spaced apart from each other by a predetermined distance on the upper portion of the lower ceramic bearing 32 . A magnetic bearing 36 is coupled and installed.

A generator 110 for generating electricity using wind power is installed between the lower ceramic bearing 30 and the upper ceramic bearing 34 .

On the other hand, a non-powered rotating unit 114 is installed at the upper end of the wind shaft 24 so that the blade 109 can be rotated even in the absence of wind.

The non-powered rotating part 114 is provided with a blade shaft lifting means 116 .

The blade shaft lifting means 116 sets the same polarity of the magnetic force generated by the levitation magnetics 60 and 61 and installs them on the upper and lower parts to face each other, respectively, to generate a repulsive force, so that the blade shaft 43 is in the air. It is preferable to be installed to float.

A wind power generator 108 provided with a blade 109 is coupled to the upper portion of the wind shaft 24 installed as described above, and the wind power generator 108 rotates the blade 109 by wind power, thereby generating a generator 110 . It is installed to generate and store electricity by driving it.

Next, FIGS. 3 and 4 are cross-sectional and plan sectional views showing the structure of the hybrid railing lighting lamp of the present invention. First, as shown in FIG. 3, the vertically installed post 10 is hollow inside. .

The lower inner pillar 18 is inserted into the inner lower end of the post 10 .

The lower inner pillar 18 is formed in a cylindrical shape, the upper end of the lower inner pillar 18 is provided with a rising protrusion 20, and the rising protrusion 20 has a concave-convex shape.

A plurality of lifting magnets 22 are attached to the upper surface of the concave-convex shape, respectively.

The plurality of lifting magnets 22 are installed so as to exert a repulsive force to push the wind shaft 24 upward.

The lower inner pillar 18 is installed on the inner side of the hollow post 10 , and the wind shaft 24 is installed at the upper portion of the lower inner pillar 18 .

At the lower end of the wind shaft 24, a concave-convex lower concave portion 26 is formed.

A plurality of lowering magnetics 28 are attached to the lower surface of the lower recessed portion 26 .

The ascending magnetic 22 and the descending magnetic 28 have opposite magnetic forces and are installed so that the same poles face each other to generate a mutual repulsive force at a symmetrical position, and the ascending magnetic 22 is the descending magnetic 28 The wind shaft 24 is pushed up by providing a strong magnetic force to push up the .

The wind shaft 24 raised by the repulsive force of the upward magnetic 22 as described above is installed in a floating state so that there is no frictional force on the upper part of the lower inner pillar 18 to have a predetermined interval.

The wind shaft 24 formed in the cylindrical shape is installed with a plurality of magnets 27 inserted in the lower outer circumferential surface, and the magnetic 27 has the same polarity to face the outward or outward direction to generate a repulsive force. This is preferable.

In addition, the lower magnetic bearing 30 is inserted into the outer portion where the magnetic 27 is installed.

The lower magnetic bearing 30 is installed to surround the outer circumferential surface of the wind power shaft 24, and has a magnetic 31 installed to face the magnetic 27, and the magnetic 27 and the magnetic 31 are It is preferable to be installed so as to be spaced apart from each other by a predetermined distance in the outward direction from the outer circumferential surface of the wind shaft 24 by exhibiting the same polarity.

As described above, by installing the lower magnetic bearing 30 , the wind power shaft 24 is pushed toward the center and floated, thereby minimizing frictional force to double the rotational force.

A lower ceramic bearing 32 is installed on the outer peripheral surface of the upper wind shaft 24 close to the lower magnetic bearing 30 so that when the wind shaft 24 rotates, it is protected from flow, shaking and impact due to rotational force. It is provided to support the outer circumferential surface for

An upper ceramic bearing 34 is coupled to the outer circumferential surface of the wind power shaft 24 at the upper portion of the lower ceramic bearing 32, and when the wind power shaft 24 rotates, it is prevented from flowing, shaking, and impact due to rotational force. It is provided to support the outer circumferential surface for protection.

On the other hand, an upper magnetic bearing 36 is coupled to an upper portion of the upper ceramic bearing 34 and a plurality of magnets 25 are inserted and installed on the outer peripheral surface of the wind shaft 24, and the magnetic 25 ) and a magnetic 37 that is installed oppositely, and the magnetic 25 and the magnetic 37 exhibit the same polarity to each other, and it is preferable to be installed so as to be spaced apart from the outer peripheral surface of the wind shaft 24 by a predetermined distance in the outward direction. do.

Subsequently, the wind shaft 24 formed in the cylindrical shape is provided with a plurality of magnets 25 inserted into the upper outer peripheral surface, and the magnetic 25 has the same polarity so as to generate a repulsive force in the outward or outward direction. It is preferable to be installed to face each other.

In addition, the upper magnetic bearing 36 is inserted into the outer portion where the magnetic 25 is installed.

The upper magnetic bearing 36 is installed to surround the outer peripheral surface of the wind shaft 24, and has a magnetic 37 installed to face the magnetic 25, and the magnetic 25 and the magnetic 37 are It is preferable to be installed so as to be spaced apart from each other by a predetermined distance in the outward direction from the outer circumferential surface of the wind shaft 24 by exhibiting the same polarity.

As described above, by installing the upper magnetic bearing 36 , the wind power shaft 24 is pushed toward the central portion and floated, thereby minimizing frictional force to double the rotational force.

A flange portion 38 is formed at the upper end of the wind power shaft 24 , and the flange portion 38 has a rotation groove 40 formed in the central portion, and a rotation magnetic field is formed on the left and right sides of the rotation groove 40 . (42) is attached.

At this time, the non-powered rotating part 114 is inserted and installed in the rotation groove 40 .

The non-powered rotating part 114 has a cylindrical blade shaft 43 is formed, a flange portion 44 is formed on the left and right sides of the blade shaft 43 , and the blade shaft 43 is formed at a lower portion of the flange portion 44 . ), the rotation protrusion 46 is formed so as to be located on the same center line.

A plurality of fixing magnets 48 are inserted and installed in the rotating protrusion 46 .

The rotating protrusion 46 is rotatably coupled to the inner portion of the rotating concave groove 40 and is installed to be positioned on the same plane as the plurality of fixed magnets 48 so that the magnetic force of the rotating magnet 42 is transmitted.

That is, by installing a fixed magnet 48 having the same polarity so that a repulsive force is generated in the magnetic force of the rotating magnetic 42, the fixed magnetic 48 by the repulsive force of the rotating magnetic 42 in a low wind or no wind state. The wind power shaft 24 is rotated by rotating it slowly by this magnetic force, and the generator 110 is operated so that a small amount of electricity is generated by low rotation to generate electricity and store electricity.

When there is no wind, the lighting 14 is turned on using the electricity generated by the magnetic low rotation structure and the remaining electricity is charged by the charging module 12 .

A blade 109 is formed on the upper portion of the blade shaft 43 , and the blade 109 operates the generator 110 while rotating by the wind to generate electricity and use the generated electricity as the lighting 14 . Or it is installed to charge the charging module (112).

The blade shaft 43 is provided with a blade shaft lifting means 116 so as to levitate the blade shaft 43 in the upward direction using magnetic force.

The blade shaft lifting means 116 is provided with a plurality of flotation magnets 60 on the upper surface of the post 10, and a plurality of levitation magnets 61 on the flange portion 44 of the blade shaft 43. These are installed facing each other to generate a repulsive force.

The levitation magnetic 60 and the levitation magnetic 61 installed as described above use the magnetic force to push each other up and lift the blade shaft 43 upwards.

4 is a view showing the structure of the non-powered rotating unit 114 of the present invention, the non-powered rotating unit 114 is formed with a flange portion 38 formed at the upper end of the wind shaft 24, the flange portion 38 of A rotation groove 30 is formed on the central upper surface, a plurality of rotation magnets 42 are provided on the upper left and right outer peripheral surfaces of the flange portion 38, and the blade shaft 43 is provided on the inner side of the rotation groove 40. A rotating protrusion 46 is formed at the lower end of the rotating protrusion 46 and a plurality of fixing magnets 48 are inserted and installed in the inner portion of the rotating protrusion 46 .

At this time, a flange portion 44 is formed on the outer peripheral surface of the blade shaft 43 .

A plurality of rotating magnets 42 are installed on the flange portion 38 of the wind shaft 24 formed as described above, have the same polarity and are inclined to generate a repulsive force toward the front, and the rotation protrusion of the blade shaft 43 It interacts with a plurality of fixed magnets 48 provided at 46 and is inclinedly installed to rotate the blade shaft 43 .

The rotating magnetic 42 is installed to have a predetermined angle A at which a repulsive force is generated with the fixed magnetic 48, and the predetermined angle A is preferably provided with an inclination of 45 degrees to 90 degrees, which is 45 degrees. By adjusting the angle so that the largest repulsive force is generated at 90 degrees by generating a repulsive force in it is to make

At this time, when the predetermined angle (A) is 45 degrees or less, it is preferable to install it so that the angle is not less than 45 degrees because a slip phenomenon that can cause a loss of magnetic force occurs.

The wind shaft 24 of the wind power generator 108 installed as described above is levitated in the air by the rising magnetic 22 installed on the lower inner pillar 18 to remove frictional force, so that the blade 109 can be rotated even in a small wind. It is implemented to be a generator, and is installed so that the rotation of the blade 109 is possible even when there is no wind by the rotating magnetic 42 and the fixed magnetic 48 of the non-powered rotating part 114. (14) can be turned on.

5 and 6 are diagrams showing the structure of a hybrid handrail lighting lamp according to an embodiment of the present invention. First, referring to FIG. 5 , the hybrid railing lighting lamp 101 is a railing lighting lamp formed of a cylindrical post 10 . A post 102 is installed, a solar power generator 107 is installed in the middle part of the railing lighting post 102 , and a wind power generator 108 is installed at the upper end of the railing lighting post 102 .

And between the photovoltaic generator 107 and the wind power generator 108, using the electricity generated by the photovoltaic generator 107 and the wind power generator 108 to illuminate the lighting 14, a handrail lighting lamp 104 this is installed

The photovoltaic generator 107 is provided with a heat collecting plate 16 in the form of a hat, and an elevating fold 17 is formed in a cone shape at the upper end of the heat collecting plate 16, and the elevating fold 17 is formed. By this, the heat collecting plate 16 is expanded upward or moved downward to return to its original shape.

The elevating fold 17 is made of a rubber or silicone material, and is folded a number of times to form a zigzag shape, and when the elevating fold flexibly stretches and unfolds and folds, the elevating fold moves downward while being folded to form a hat return to the form of

The photovoltaic generator 107 is provided with a light collecting and elevating means 111 in the lower inner side of the heat collecting plate 16 .

The light collecting means 111 raises and spreads the photovoltaic generator 107 to form numerous reflected lights while the sunlight is incident, thereby increasing the photovoltaic integration efficiency by more than twice.

The light collecting and elevating means 111 includes a post bracket 50 fixedly installed on the outer edge of the post 10 , and a motor 52 fixed to an upper surface of one side of the post bracket 50 .

An elevating screw 54 is installed in the motor 52 , and a heat collecting plate bracket 56 is fixedly installed at an upper end of the elevating screw 54 .

The heat collecting plate bracket 56 is fixed to the lower surface of the heat collecting plate 16 , and the heat collecting plate 16 is expanded and folded while moving upward by the operation of the elevating screw 54 .

That is, as the motor 52 rotates forward, the elevating screw 54 fixed to the lower portion of the heat collecting plate 16 and connected to the motor 52 rotates and rises, and as the elevating screw 54 rises The elevating folded portion 17 installed in the center of the heat collecting plate 16 is flexibly stretched and unfolded in the upward and outer circumferential directions.

At this time, as the sunlight incident on the heat collecting plate 16 is reflected to each other as shown in FIG. 6 , the light collecting efficiency increases.

Then, as the motor 52 reversely rotates, the lifting screw 54 connected to the motor rotates and is pulled while descending, and at the same time the heat collecting plate 16 is pulled, the lifting and folding part 17 is folded to its original state. will return to

As such, the photovoltaic generator 107 operates the light collecting operation means 109 to expand the heat collecting plate 16 in the afternoon when sunlight is strongest, thereby increasing the light collecting efficiency by 2-3 times, and in normal times, the original position return to

7 is a perspective view showing the cover structure of the wind power generator of the hybrid railing lighting of the present invention, the wind power generator 108 is installed to cover the outside, and is formed so that the wind flows in only one direction, so that the efficiency of wind energy can be improved. The wind generator cover 118 is installed so that

The wind power generator cover 118 of the wind power generator 108 includes a cover body 62 made of a cylindrical shape, and a plurality of wind guides 66 protruding from the cover body 62 .

At this time, the cover body 62 is formed with a ventilation hole 64 made of a plurality of through-holes, and is formed in the shape of a giyeok character (a) so that the wind flows in only one direction through the wind guide hole 66 .

The wind flowing into the wind guide port 66 is introduced through the vent 64, which is narrowed by demagnetization, thereby increasing the strength of the wind and increasing the power to turn the blade 109, thereby efficiently acquiring wind energy. .

The embodiments described in this specification and the configurations shown in the drawings relate to one most preferred embodiment of the present invention, and do not represent all of the technical spirit of the present invention, so various equivalents and modifications that can be substituted for them are It should be understood that there may be examples.

Therefore, the present invention is not limited to the presented embodiment, and within the equivalent scope of the technical spirit of the present invention and the technical spirit described in the claims to be described below by those of ordinary skill in the technical field to which the present invention pertains. There may be various modifications and changeable embodiments.

10: holding 12: lighting horizontal bar
14: lighting 16: heat collecting plate
18: lower inner pillar 20: rising protrusion
22: upward magnetic 24: wind shaft
26: descending recess 28: descending magnetic
30: lower magnetic bearing 32: lower ceramic bearing
34: upper ceramic bearing 36: upper magnetic bearing
38: flange portion 40: rotating groove
42: fixed magnetic 44: flange portion
46: rotating protrusion 48: rotating magnetic
50: holding bracket 52: motor
54: rising screw 56: heat collecting plate bracket
60,61: floating magnetic 62: cover body
64: ventilation hole 66: wind guide hole
100: hybrid railing lighting 102: railing lighting post
104: handrail lighting 106: solar generator
108: wind power generator 111: light collecting means
116: blade lifting means 118: wind generator cover

Claims (4)

In the handrail lighting, etc. where lighting is installed on the railing or fence,
A balustrade lighting lamp post 102 having a hollow cylindrical post 10 and having a lower inner column 18 installed on the inner side of the post 10;
a photovoltaic generator 106 having a heat collecting plate 16 installed on the upper surface of the railing light 104 to collect and generate solar light;
A wind power generator 108 having a wind shaft 24 that is levitated in the air by magnetic force to minimize frictional force so that the blade 109 rotates and generates power,
A rising protrusion 20 is formed on the upper portion of the lower inner pillar 18 , a plurality of rising magnets 22 are installed on the upper surface of the rising protrusion 20 , and a descending recess at the lower end of the wind shaft 24 . 26 is formed, and a plurality of descending magnets 28 facing the ascending magnetic 22 are installed on the lower surface of the descending recess 26, and between the ascending magnetic 22 and the descending magnetic 28 The blade 109 and the blade 109 to minimize friction by levitating the wind shaft 24 in the air by installing to generate a mutual repulsion force:
Hybrid handrail lighting, characterized in that it protects the blade 109 of the wind power generator 108 and comprises a wind power generator cover 118 installed on the outer side of the wind power generator so as to introduce only wind in one direction.
The method of claim 1,
A lower magnetic bearing 30 into which a magnetic 31 is interpolated is installed on the lower outer circumferential surface of the wind shaft 24,
A lower ceramic bearing 32 for preventing and supporting the flow of the wind shaft 24 is installed in an upper portion close to the lower magnetic bearing 30,
An upper ceramic bearing 34 is installed on the upper portion of the lower ceramic bearing 32 to prevent and support the flow of the wind shaft 24 spaced apart by a predetermined distance,
An upper magnetic bearing 36 in which a magnetic 37 is interpolated is installed at an upper portion adjacent to the upper ceramic bearing 34,
Hybrid handrail lighting, characterized in that the magnetic (31) and the magnetic (37) are installed to face each other to generate a repulsive force and installed on the wind shaft (24).
The method of claim 1,
The blade shaft 43 of the blade 109 of the wind power generator 108 further includes a non-powered rotating part 114 to generate electricity by rotating the blade 109 by magnetic force when there is no wind,
The non-powered rotating part 114,
A flange portion 38 is formed on the upper portion of the wind shaft 24, and a rotation groove 40 is formed in the central portion of the flange portion 38,
A plurality of rotating magnetics 42 are provided on the upper surface of the flange portion 38,
A rotary protrusion 46 coupled to the rotary recess 40 is formed at a lower portion of the blade shaft 43, and a plurality of fixing magnets 48 are provided on the rotary protrusion 46,
The rotating magnetic 42 and the fixed magnetic 48 are installed to generate a mutual repulsive force, so that the fixed magnetic 48 is pushed in one direction by the repulsive force of the rotating magnetic 42 and at the same time the blade shaft 43 is rotated. Hybrid handrail lighting, characterized in that it is installed.
The method of claim 1,
A plurality of levitation magnets (60) installed on the upper surface of the holding (10) and;
The plurality of levitation magnets (60) are opposite to each other and are installed to face each other so as to generate a mutual repulsive force, and a plurality of levitation magnets (61) are inserted and installed in the flange portion (44) of the blade shaft (43).
Hybrid handrail lighting, characterized in that it comprises a blade shaft lifting means (116) installed to float the blade shaft (43) provided with the blade (109) by a predetermined distance in the air.

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